Methods and systems of an adjustable sleeping system

ABSTRACT

An adjustable sleeping system. At least some of the example embodiments are an adjustable sleeping system comprising a plurality of spring modules arranged in a first column, each spring module defines a row within the first column. Each spring module may comprise a rail and a plurality of adjustable spring assembles coupled along the rail. Each adjustable spring assembly may comprise a motor coupled to the rail, a lead screw coupled to a rotor of the motor, a spring plate coupled to the lead screw, and a spring coupled to the spring plate. A bed controller is communicatively coupled to each spring module, and the bed controller is configured to selectively control a load carried by each spring assembly.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of provisional application Ser. No.62/779,629, filed Dec. 14, 2018, titled “Adjustable Sleeping System”,and the provisional application is incorporated by reference herein asif reproduced in full below.

BACKGROUND

Getting a good night's sleep is important, not only from the perspectiveof day-to-day cognitive functions, but also from the perspective of longterm health. Some studies suggest that lack of sleep, or lack ofsufficiently restful sleep, has long term health consequences. The longterm health consequences include increased risk of dementia andAlzheimer's disease. Some factors that adversely affect the ability toget a good night's sleep are physiological, such as snoring, centralapnea, obstructive apnea, and restless leg syndrome. However, otherfactors are environmental, such as the compliance of the sleepingsurface upon which sleep is attempted, and sleeping position (thoughsome physiological factors are sleep position dependent).

Many mattresses and beds purport to increase the restfulness of sleep.For example, one attempt in recent years is based on mattresses made ofcombinations of closed- and open-cell foams that purport to reduce highforce areas regardless of sleep position, and to reduce communication ofmovement to sleeping partners. Other attempts in recent years use airbladders to create individual pockets of support, usually in horizontalrows across the width of a mattress. The air bladder mattresses enablechanging air pressure within the bladders, and thus changing the forcecarried by each bladder. Each system has its respective drawbacks.

Any system and/or method which increases user comfort and flexibility ofcontrol would provide a competitive advantage in the marketplace.

BRIEF DESCRIPTION OF THE DRAWINGS

For a detailed description of example embodiments, reference will now bemade to the accompanying drawings in which:

FIG. 1 shows a perspective view of an adjustable sleeping system inaccordance with at least some embodiments;

FIG. 2 shows a perspective view of a spring module in accordance with atleast some embodiments;

FIG. 3 shows a side elevation view of a spring module and bed frameduring installation of the spring module, and in accordance with atleast some embodiments;

FIG. 4 shows a cross-sectional view of spring rail coupled to anunderlying first and second frame rails, in accordance with at leastsome embodiments;

FIG. 5 shows a partial perspective view of the frame rails of the bedframe in accordance with at least some embodiments;

FIG. 6 shows an exploded perspective view of a spring module inaccordance with at least some embodiments;

FIG. 7 shows a perspective view of an adjustable spring assembly(without the main spring), and in accordance with at least someembodiments;

FIG. 8 shows a bottom view of the suspension member in accordance withat least some embodiments;

FIG. 9 shows a perspective view of an adjustable spring assembly coupledto a spring rail in accordance with at least some embodiments;

FIG. 10 shows a partial perspective, partial cut-away, view of anadjustable spring assembly and spring rail in accordance with at leastsome embodiments;

FIG. 11 shows a block diagram of the control PCB in accordance with atleast some embodiments;

FIG. 12 shows a side elevation, partial cross-sectional view, of aportion of an adjustable spring assembly in accordance with at leastsome embodiments; and

FIG. 13 shows a method of assembly of a spring module for an adjustablesleeping system, and in accordance with at least some embodiments.

DEFINITIONS

Various terms are used to refer to particular system components.Different companies may refer to a component by different names—thisdocument does not intend to distinguish between components that differin name but not function. In the following discussion and in the claims,the terms “including” and “comprising” are used in an open-endedfashion, and thus should be interpreted to mean “including, but notlimited to. . . .” Also, the term “couple” or “couples” is intended tomean either an indirect or direct connection. Thus, if a first devicecouples to a second device, that connection may be through a directconnection or through an indirect connection via other devices andconnections.

The adjustable spring assemblies are described herein to have multiplerotational orientations relative to the spring rail (and the rotationalorientations about a longitudinal central axis of a lead screw).However, having a first rotational orientation and a second rotationalorientation shall not be read to require that the rotationalorientations be simultaneously present.

“Controller” shall mean, alone or in combination, individual circuitcomponents, an application specific integrated circuit (ASIC), amicrocontroller (with controlling software), and/or a processor (withcontrolling software), configured to read signals and take controlactions responsive to such signals.

DETAILED DESCRIPTION

The following discussion is directed to various embodiments of theinvention. Although one or more of these embodiments may be preferred,the embodiments disclosed should not be interpreted, or otherwise used,as limiting the scope of the disclosure, including the claims. Inaddition, one skilled in the art will understand that the followingdescription has broad application, and the discussion of any embodimentis meant only to be exemplary of that embodiment, and not intended tointimate that the scope of the disclosure, including the claims, islimited to that embodiment.

Various embodiments are directed to adjustable sleeping systems. Moreparticular, example embodiments are directed to an adjustable sleepingsystem comprising a plurality of spring modules coupled to an underlyingbed frame. Each spring module may comprise a plurality of adjustablespring assemblies, and the weight or force carried by each adjustablespring assembly may be changed to accomplish any of a variety offirmness settings or functions. The specification first turns to a highlevel overview of the adjustable sleeping system in accordance withexample embodiments.

FIG. 1 shows a perspective view of an adjustable sleeping system 100 inaccordance with at least some embodiments. In particular, the exampleadjustable sleeping system 100 defines a length L, a width W, and asleeping surface 102. The length L and width W may be any suitable size,such as a cot size, a single size, a twin size, a twin XL size, a fullsize, a Queen size, a “California” King, King size, or specialty sizes(e.g., for boats, motor homes, travel trailers). In some cases, theoverall bed may comprise two adjustable sleeping systems 100 arrangedside-by-side (e.g., two twin XL size beds side-by-side to form a Kingsize). The adjustable sleeping system 100 further comprises a pluralityof spring modules 104. In some cases, between 15 and 80 spring modules104 may be used, in one example case between 20 and 30 spring modules104 may be used, and in some cases 25 spring modules are used. FIG. 1labels only four of the spring modules 104 (104A-104D) so as not tounduly complicate the figure. The spring modules are modular componentsthat may be placed at any location, and thus a single spring module willbe referred to as “spring module 104” and groups of spring modules willbe referred to as “spring modules 104”. The spring modules 104mechanically coupled to a bed frame 106 comprising a first frame rail108 and a second frame rail 110.

In the example system, an upper surface of the spring modules 104 (theupper surface not visible in FIG. 1) is covered with a topper or overlay112, such as open-cell or closed-cell foam. In one example embodimentthe overlay 112 comprises a foam padding having a thickness of threeinches (measured perpendicularly to the sleeping surface 102). Otherthicknesses, both greater and smaller, and other constituent materials,may be used. In the example of FIG. 1, the overlay 112 wraps around thehead end 114 of the adjustable sleeping system 100, and also wrapsaround the foot end 116 of the adjustable sleeping system 100. In othercases, the wrapping aspects of the overlay 112 may be omitted, and aspring module 104 on the head end 114 will be exposed on the head end114, and another spring module 104 will be exposed on the foot end 116.In yet still other cases, the overlay 112 may be omitted entirely, andthus an upper surface defined by the spring modules 104 may define thesleeping surface 102.

Still referring to FIG. 1, the spring modules 104 can be considered tobe arranged in a column along the length L, with each spring module 104defining a row within the column. Each spring module 104 is coupled tothe first frame rail 108 of the bed frame 106, and each spring module104 is coupled to the second frame rail 110 of the bed frame 106.

The adjustable sleeping system 100 further comprises a bed controller118 communicatively and controllably coupled to each spring module 104,and as discussed more below communicatively and controllably coupled tothe adjustable spring assemblies (not visible in FIG. 1) within eachspring module 104. The bed controller 118 is configured to selectivelycontrol a load carried by each spring module 104, and more particularlyto selectively control a load carried by each adjustable spring assemblywithin each spring module 104. The bed controller 118 may take anysuitable form, such as a computer system, individual circuit components,an application specific integrated circuit (ASIC), a microcontroller(with controlling software), a processor (with controlling software), orcombinations thereof configured to read signals and take control actionsresponsive to such signals.

FIG. 2 shows a perspective, partial cut-away, view of a spring module104 in accordance with at least some embodiments. In particular, FIG. 2shows a spring rail 200, a slip cover 202, and a baffle box 204. Thespring rail 200 in accordance with example embodiment is a metal railthat forms the base of the spring module 104. In some cases the springrail 200 has a cross-sectional shape in the form of an inverted channelshape, with the walls or legs of the channel pointing downward (i.e.,downward referenced to the force of gravity), and having a flat uppersurface. The spring rail 200 is discussed in greater detail below.

The example slip cover 202 is a cover of fabric material. The slip cover202 wraps around a bottom of the spring rail 200 on opposing ends 206and 208 of the spring rail 200. When assembled into an adjustablesleeping system, either or both of the ends 206 and 208 may be thelocation where a fitted sheet wraps around the overall adjustablesleeping system. In example systems, the slip cover 202 does not fullyenvelope the spring rail 200, as the spring rail 200 couples to anunderlying bed frame 106 (FIG. 1), and the spring rail 200 is thusexposed on a lower side. When assembled into an adjustable sleepingsystem, one or both of the short sides of the spring module 104 may bevisible along the length L (FIG. 1) of the adjustable sleeping system.For example, when assembled the short side 210 may be visible along thelength L of the adjustable sleeping system. If the spring modules 104are part of the twin-size bed, the opposite short side (not visible inFIG. 2) would also be exposed and visible. On the other hand, if thespring modules 104 are part of a Queen- or King-size bed, only one ofthe short sides may be visible as another twin-size set of springmodules 104 will block exposure of the second side. Because of thevisibility of the short sides (e.g., short side 210), the slip cover 202material may be selected to accomplish an overall industrial designand/or marketing feature. Thus, the example slip cover 202 covers theshort side 210, the opposite short side not visible in FIG. 2, the top224, the long side 226, the opposite long side not visible in FIG. 2,and portions of the spring rail 200.

In order to assemble the adjustable sleeping system, a plurality ofspring modules 104 are coupled side-by-side (e.g., as shown in FIG. 1).To keep objects from slipping down between spring modules 104, and/or toform a stable upper surface that may be the sleeping surface (or thatmay be parallel to the sleeping surface 102), the example slip cover 202also defines affixation devices 212 and 214 across an upper portion ofthe slip cover 202. The affixation devices 212 and 214 are disposedalong the long dimension of the spring module 104. In some cases, and asshown, the affixation devices 212 and 214 are elements of a zipper. Forexample, affixation device 214 may include a slider 216 and a pluralityof teeth. Thus, the affixation device 214 is configured to couple to acomplementary affixation device on an adjacent spring module. Theaffixation device 212 may include a pin 218 and a plurality of teeth.Thus, the affixation device 212 is configured to couple to acomplementary affixation device on an adjacent spring module. However,the affixation devices 212 and 214 may take any suitable form, such as aseries of buttons and corresponding series of button holes, or eyeletsthrough which laces are weaved. In the example embodiments of FIG. 2,the affixation devices 212 and 214 are shown at the upper portion of thespring module 104, and particularly along seams of the slip cover 202 atthe intersection of the top 224 and long side 226 of the spring module104; however, in other cases the affixation devices 212 and 214 need notbe precisely at the upper corners, and may be disposed lower. Inparticular, the spring module 104 may define a height H (e.g., between10 and 20 inches, in some cases between 12 and 18 inches), and theaffixation devices may run along the long dimension at a distance halfthe height H or less from the intersection of the top 224 and long side226, and in some cases a quarter of the height H or less from the fromthe intersection of the top 224 and long side 226.

The example slip cover 202 is shown in partial cut-away to expose theunderlying baffle box 204 of fabric coupled to the spring rail 200. Aswill be discussed in greater detail below, the baffle box 204 covers andseparates the upper components of adjustable spring assemblies (notvisible in FIG. 2) of the spring module 104. The dashed lines associatedwith the baffle box 204 show locations of baffles within the baffle box204, and main springs and other components of the adjustable springassemblies extend upward into pockets formed by the baffles within thebaffle box 204. The baffle box 204 is likewise shown in partial cut-awayto show an example main spring 220 and lead screw 222 of an adjustablespring assembly. The baffle box 204 and adjustable spring assemblies(e.g., one adjustable spring assembly associated with main spring 220and lead screw 222) are discussed in greater detail below. Nevertheless,the baffle box 204, and thus the pockets formed within the baffle box204, are coupled on a lower end to the spring rail 200, such as byaffixation devices 228. As discussed more below, in some cases thebaffle box 204 is coupled in such a way that tension created in the mainsprings (e.g., main spring 220) by the baffle box 204 is not transmitteddirectly to the spring rail 200, so as not to pre-load force sensorsassociated with the adjustable spring assemblies (the coupling discussedmore below).

Returning to FIG. 1, assembly of an adjustable sleeping system inaccordance with various embodiments may involve coupling a first springmodule (e.g., spring module 104A) to the bed frame 106. Next, the methodmay comprise coupling a second spring module (e.g., spring module 104B)to the bed frame 106. The process of coupling spring modules continues(e.g., with spring module 104C) until the last spring module (e.g.,spring module 104D) has been coupled to the bed frame 106. In somecases, just after a spring module 104 is coupled to the bed frame 106,the upper edge of the spring module is coupled to the upper edge of theadjacent spring module (e.g., using affixation devices 212 and 214discussed above). In other cases, the assembly may wait until some orall the spring modules 104 are coupled to the bed frame before couplingthe affixation devices to secure upper ends of the spring modules 104.Once assembled, the upper surfaces of the spring modules 104 define asurface parallel to a sleeping surface of the adjustable sleeping system100 of FIG. 1. In cases where the overlay 112 is omitted, the uppersurfaces 224 (FIG. 2) of the spring modules 104 may directly formsleeping surface.

FIG. 3 shows a side elevation view of a spring module 104 and bed frame106 during installation of the spring module 104, and in accordance withat least some embodiments. Visible in FIG. 3 are the spring module 104,the first frame rail 108, and the second frame rail 110 (where the framerails 108 and 110 are part of the bed frame 106). The spring module 104of FIG. 3 includes the slip cover 202, and the exposed portion of thespring rail 200. In example embodiments, coupling each spring module 104to the bed frame 106 is a two-step process. First, the spring module 104is coupled to the first frame rail 108. Though not visible in FIG. 3,the first frame rail 108 extends along and parallel to the length L(FIG. 1, and where the length L is into and out of the page in the viewof FIG. 3). The second frame rail 110 also runs along and parallel tothe length L (again, into and out of the page in the view of FIG. 3).

FIG. 3 shows a first step in the example process of coupling the springmodule 104 to the underlying bed frame 106, where the spring module 104is in operational relationship to the first frame rail 108 but not incontact with the second frame rail 110. In example cases, the springmodule 104 is placed on the first frame rail 108, and then the springmodule 104 is slid across the first frame rail 108 until a first hingemember of the spring module 104 couples to a second hinge member of thefirst frame rail 108. The direction of the sliding is shown by arrow300. More particularly still, the spring rail 200 is placed in directcontact with the frame rail 108 at an angle such that the spring module104 initially only contacts the first frame rail 108. The spring module104 is then slid in a direction indicated by arrow 300 until the firstand second hinge members couple together. In other cases, the slidingmay be omitted, and the spring module 104 may be directly placed againstthe frame rail 108 in such a way that the hinge members couple together.Any suitable hinge member on the spring module 104, and anycomplementary hinge member on the first frame rail 108, may be used.Example hinge members are discussed below. Nevertheless, when coupledthe first and second hinge members define a rotational axis, such asrotational axis 302 parallel to the first frame rail 108. In the view ofFIG. 3, the rotational axis 302 is perpendicular to the plane of thepage, and thus the rotational axis 302 is shown as a point. Coupling thespring module 104 may then further comprise rotating the spring module104 about the rotational axis 302, with the rotation shown by curvedarrow 304. The rotation of the spring module 104 moves the elevatedportion of spring module 104 toward the second frame rail 110, and thespring module 104 then latches to the second frame rail 110 (the latchedspring module not shown in FIG. 3, but is shown FIG. 1). The process isrepeated for each spring module 104 (e.g., spring module 104A, springmodule 104B, spring module 104C, and spring module 104D) in theadjustable sleeping system.

In at least some cases, the rotation and latching of the spring module104 also acts to electrically couple an electrical connector of thespring module 104 to an electrical connector associated with the secondframe rail 110. Electrically coupling the connectors communicativelycouples the spring module 104 to the bed controller 118 (FIG. 1). Moreparticularly, electrically coupling the connectors communicativelycouples the adjustable spring assemblies (discussed more below), whichmake up the spring module 104, to the bed controller 118. FIG. 3 showsan electrical connector 306 rigidly coupled on an inside surface of thesecond frame rail 110. That is, in the example of FIG. 3 the surface towhich the electrical connector 306 is coupled is a surface that facesthe first frame rail 108. The electrical connector 306 extends upwardabove a seating surface 308 such that, when the spring module 104 iscoupled to the second frame rail 110, the electrical connector extendsupward in a channel defined by spring rail 200. FIG. 3 also shows, in apartial cutaway, a corresponding electrical connector 310 within thechannel defined by the spring rail 200. Thus, in some cases the act ofrotating the spring module 104 about the rotational axis 302 not onlyresults in latching of the spring module 104 to the second frame rail110, but also mechanically and electrically couples the electricalconnector 310 of the spring module 104 to the electrical connector 306attached to the second frame rail 110. Any suitable electricalconnectors may be used. In alternative embodiments, the electricalconnector 306 may be partially disposed within an interior volume of thesecond frame rail 110, with the electrical connector 306 extending abovethe seating surface, and thus power and communication conductors mayextend along an interior volume of the second frame rail. In yet stillother cases, coupling the electrical connectors may be disassociatedfrom latching of the spring module to the second frame rail 110. Forexample, coupling the electrical connectors may be a separate step, orthe electrical connectors may be associated with the location of thefirst frame rail 108 such that sliding the spring module 104 across thefirst frame rail 108 results in mechanically and electrically couplingthe connectors.

FIG. 4 shows a cross-sectional view of spring rail coupled to anunderlying first and second frame rails, in accordance with at leastsome embodiments. In particular, visible in FIG. 4 are the first framerail 108, the second frame rail 110, and the spring rail 200. The springrail 200 is shown without the slip cover, without the baffle cover, andwithout the adjustable spring assemblies, all so as not to furthercomplicate the figure. The first frame rail 108 and second frame rail110 are show as solid objects, but in other cases the frame rails may behollow (e.g., tubing with a square or rectangular cross-section). Thefirst frame rail 108 defines an upwardly projecting wall 400 thatextends parallel to the length L (FIG. 1). In the view of FIG. 4, theupwardly projecting wall extends into and out of the plane of the page.Though the upwardly projecting wall 400 is shown on the outer edge ofthe first frame rail 108 (e.g., outer relative to location of the secondframe rail 110), the upwardly projecting wall 400 may be at any suitablelocation (e.g., inner edge, middle). At the location of each springmodule, the example upwardly projecting wall 400 has two slots, one slotfor each downwardly projecting wall or downwardly projecting leg of aspring rail 200 (e.g., downwardly projecting 402). The slots are notvisible in FIG. 4, and only one downwardly projecting leg visible in thecross-section of FIG. 4. Nevertheless, as part of coupling the springmodule 104 to the first frame rail 108, each downwardly projecting legof the spring rail 200 is placed within a corresponding slot defined inthe upwardly projecting wall 400.

In the example embodiment shown in FIG. 4, the spring rail 200 shows twoexample hinge members associated with the first frame rail 108, but itis to be understood that the two example hinge members need not besimultaneously present. The first example hinge member is a tab 404projecting downward below the bottom edge of the downwardly projectingleg 402. In some cases, both the downwardly projecting legs of thespring rail 200 will have a corresponding tab. When the spring rail 200is placed on and slid across the first frame rail 108 as part of theinstallation, the tab 404 acts as a stop to orient the spring rail 200relative to the first frame rail 108. The tab 404 further holds a thedownwardly projecting leg 604, and thus the spring module 104, in properorientation as the spring rail 200 is rotated to contact the secondframe rail 110. In some cases, one or both of the downwardly projectinglegs (e.g., downwardly projecting leg 402) has an inwardly projectingtab, and as the opposite end of the spring rail 200 latches to thesecond frame rail 110, the inwardly projecting tab engages acomplementary feature in the upwardly projecting wall 400. Theengagement of the inwardly projecting tab biases the spring rail 200toward the first frame rail 108. In some cases, and as shown, the zonebetween the bottom edge of downwardly projecting leg 402 and the contactsurface of the first frame rail 108 includes a polymeric material 406.The polymeric material 406 may provide an opposing force to the biastoward the first frame rail 108 provided by the spring rail 200, and mayalso reduce the conduction of vibrations from the spring module to theunderlying first frame rail 108.

The second example hinge member visible in FIG. 4 is a reverse-“S”shaped spring clip 408 (hereafter referred to as “tusk 408” given theresemblance to a tusk of an elephant). The example tusk 408 defines astop portion 410 being a rounded upper portion, a tusk portion 412, anda connection portion 414. The stop portion 410 and tusk portion are freeto move in a plane parallel to a plane defined by the inwardly facingsurface of the downwardly projecting leg 402, while the connectionportion 414 is rigidly coupled to the downwardly projecting leg 402. Inthese example embodiments, when the spring rail 200 is placed on andslid across the first frame rail 108 as part of the installation, thestop portion 410 abuts a portion of the upwardly projecting wall 400 andthus acts as a stop to orient the spring rail 200 relative to the firstframe rail 108. In addition to, or in place of, the stop portion 410abutting the upwardly projecting wall 400, the tab 404 may provide thefunctionality. As the spring rail 200 is rotated downward to contact thesecond frame rail 110, the tusk portion 412 engages a complementaryfeature in the upwardly projecting wall 400. The engagement of the tuskportion 412 (because of the spring action of the tusk 408) and acorresponding hinge member in the form of the upwardly projecting wall400, biases the spring rail 200 toward the first frame rail 108. Andagain in the embodiments using the tusk 408, the zone between the bottomedge of downwardly projecting leg 402 and the contact surface of thefirst frame rail 108 may include the polymeric material 406.

Still referring to FIG. 4, and particularly referring to the interactionof the spring rail 200 with the second frame rail 110. The second framerail 110 also defines an upwardly projecting wall 416 that extendsparallel to the length L (FIG. 1) of the adjustable sleeping system. Inthe view of FIG. 4, the upwardly projecting wall 416 extends into andout of the plane of the page. Though the upwardly projecting wall 416 isshown on the outer edge of the second frame rail 110 (e.g., outerrelative to location of the first frame rail 108), the upwardlyprojecting wall 416 may be at any suitable location (e.g., inner edge,middle). At the location of each spring module, the upwardly projectingwall 416 has two slots, one slot for each downwardly projecting leg of aspring rail 200. The slots are not visible in FIG. 4, and only onedownwardly projecting leg 402 of the spring rail 200 is shown in thecross-sectional view of FIG. 4. Nevertheless, as part of coupling thespring module 104 to the second frame rail 110, each downwardlyprojecting leg 402 of the spring rail 200 is placed within acorresponding slot defined in the upwardly projecting wall 416. Theslots within the upwardly projecting wall 416 are considered latchingmembers, as the slots hold the spring rail 200 in the proper locationalong the second frame rail 110.

In the example embodiment shown in FIG. 4, the spring rail 200 has anexample latch member in the form of spring latch 418. In particular, theexample spring latch 418 (shown in partial cross-sectional form) definesa proximal portion 420 rigidly coupled to the spring rail 200, and moreparticularly rigidly coupled to the downwardly projecting leg 402. Insome cases, the spring latch 418 is rigidly coupled on its proximal end420 to both downwardly projecting legs of the spring rail 200. As thespring module is rotated toward the second frame rail 110 duringinstallation, the spring latch 418 is initially deflected by an outeredge of the spring rail 200. In particular, the interaction of aninwardly protruding ridge 422 (hereafter just ridge 422) causesdeflection of the spring latch 418 as the ridge moves across the secondframe rail 110. Once the ridge 422 clears the lower boundary of thesecond frame rail 110, the spring action of the spring latch 418 causesthe ridge 422 to couple beneath the second frame rail 110. The movementof the spring latch 418 is shown by double-headed arrow 424. In somecases, the spring latch 418 may be sufficient to couple or latch thespring rail 200 the second frame rail 110, but in other cases eachdownwardly projecting leg of the spring rail 200 (e.g., downwardlyprojecting leg 402) may further include a tab 426 to help ensure thatthe spring latch 418 is properly aligned. Depending on the shape of theridge 422, the spring latch 418 may provide a force that biases thespring rail 200 toward the second frame rail 110 when in the latchedorientation.

In some example cases, the zone between the bottom edge of downwardlyprojecting leg 402 and the contact surface of the second frame rail 110includes a polymeric material 428. The polymeric material 428 mayprovide an opposing force to the bias toward the second frame rail 110provided by the spring latch 418, and may also reduce the conduction ofvibrations from the spring module to the underlying second frame rail110.

FIG. 5 shows a partial perspective view of the frame rails of the bedframe in accordance with at least some embodiments. In particular, FIG.5 shows a portion of the first frame rail 108 and the second frame rail110. Visible in FIG. 5 are a portion of the upwardly projecting wall 400of the first frame rail 108, as well as a portion of the upwardlyprojecting wall 416 of the second frame rail 110. The example upwardlyprojecting wall 400 defines two zones where respective spring modulesmay couple, the zones being zone 500 and zone 502. The example upwardlyprojecting wall 416 also defines two zones where spring modules maycouple, and those zones are also designated as zones 500 and 502 to showthe correspondence of the locations with respect to the first frame rail108. Thus, a spring module coupled to the first and second frame rails108 and 110 will couple within a zone. FIG. 5 shows two complete zones500 and 502, as well as a partial zone to the left on each frame rail.Only two zones are shown so as to provide sufficient detail of the hingeand latch members in those zones, and also to acknowledge that in atleast some embodiments the frame rails 108 and 110 may be contiguousover less than all the spring modules that make up an adjustablesleeping system (e.g., system that implement separate inclination of thehead, torso, and legs).

Referring initially to the first frame rail 108, and specifically zone500, as illustrative of any zone along the first frame rail 108. Theupwardly projecting wall 400 defines two slots 504 and 506. The slots504 and 506 extend from the upper surface of the upwardly projectingwall 400 to the seating surface 512. In the example case of FIG. 5, theslot 504 is an “L”-shaped slot, and slot 506 is a mirror image acrossthe zone such that the center piece between the slots forms a “T” shape.In embodiments using the tusk 408 (FIG. 4), the wider portion of the “T”shape is the location where the stop portion 410 (FIG. 4) of the tusk408 abuts upwardly projecting wall 400 to control the position of thespring rail in its movement across the first frame rail 108 duringinstallation. The interior shoulder region formed by the “T” shape oneach side (in this case, the shoulder created by an absence of material)is a surface that enables application of the biasing force. In theexample embodiments using the tusk 408, the tusk portion 412 interactswith the shoulder region created by one side of the “T” shape to providethe biasing force. If two tusks 408 are used on a single spring rail,each tusk will provide a portion of the biasing force. Regardless, theslots 504 and 506 are illustrative of hinge members defined on the firstframe rail 108.

Referring now to the second frame rail 110, and specifically zone 500,as illustrative of any zone along the second frame rail 110. Theupwardly projecting wall 416 defines two slots 508 and 510. The slots508 and 510 extend from the upper surface of the upwardly projectingwall 416 to the seating surface 308. The example slots 508 and 510 havea uniform width along their length, and the example slots 508 and 510act to guide the downwardly projecting legs of a spring rail (e.g.,downwardly projecting leg 402 of spring rail 200 of FIG. 4) into contactwith the seating surface 308. The slots 508 and 510, along with theoutside surface of the second frame rail 110 across which ridge 422slides, are alone or in combination illustrative of latch membersdefined on the second frame rail 110. The specification now turns to amore detailed discussion of the example spring modules 104.

FIG. 6 shows an exploded perspective view of a spring module inaccordance with at least some embodiments. In particular, visible inFIG. 6 are the baffle box 204, the spring rail 200, as well as aplurality of adjustable spring assemblies 600. In some cases, between 8and 40 adjustable spring assemblies 600 are used within each springmodule 104, in one example case between 10 and 15 adjustable springassemblies 104, and in a particular case 13 adjustable spring assemblies600 are used. FIG. 6 labels only four of the adjustable springassemblies 600 (600A-600D) so as not to unduly complicate the figure.The adjustable spring assemblies are modular components that may beplaced at any location within a spring module 104, and thus a singleadjustable spring assembly will be referred to as “adjustable springassembly 600” and groups of adjustable spring assemblies will bereferred to as “adjustable spring assemblies 600”. The slip cover 202(FIG. 2) is not included in FIG. 6 so as not to further complicate thefigure. The various example components will be addressed in turn,starting with a more detailed description of the spring rail 200.

The example spring rail 200 defines a long dimension or length L_(SR).When the example spring module 104 is assembled into an adjustablesleeping system 100 (FIG. 1), the length L_(SR) is parallel to the widthW (FIG. 1) and perpendicular to the length L (FIG. 1) of the adjustablesleeping system 100. In cases where the adjustable sleeping system 100is a cot width or a twin width, the length L_(SR) will be about same asthe width W. In cases where the overall adjustable sleeping system 100is a Queen size, a “California” King, or a King size, the length L_(SR)may be half the overall width W. The spring rail 200 also defines awidth W_(SR). When the example spring module 104 is assembled into anadjustable sleeping system 100, the width W_(SR) is parallel to thelength L and perpendicular to the width W of the adjustable sleepingsystem 100. In example cases the width W_(SR) is between and including 1inch and 6 inches, and in some cases the width W_(SR) is 3 inches. Theexample spring rail 200 further comprises an upper surface 602 and acorresponding lower surface (not visible in FIG. 6). Moreover, FIG. 6shows the example spring rail 200 to have both the downwardly projectingleg 402 on a first side of the spring rail 200 and running along thelength L_(SR), and a downwardly projecting wall or downwardly projectingleg 604 on the opposite side of the spring rail 200 and running alongthe length L_(SR). Further, the example spring rail 200 defines aplurality of apertures 606. The number of apertures 606 may corresponddirectly to the number of adjustable spring assemblies 600, and thus insome cases between 8 and 40 apertures 600 are present within each springmodule 104. FIG. 6 labels only four of the apertures 606 (606A-606D) soas not to unduly complicate the figure. Each individual aperture 606will be referred to as “aperture 606,” and groups of apertures will bereferred to as “apertures 606.” The apertures 606 are spaced along thelength L_(SR), and each aperture 606 extends from the upper surface 602to the lower surface of the spring rail 200. In example embodiments, thespring rail 200 is made of metallic material, but any suitable material(e.g., high strength plastic, fiber glass) may be used.

The discussion now turns to the adjustable spring assemblies 600.Referring to adjustable spring assembly 600A as representative of allthe adjustable spring assemblies, the example adjustable spring assembly600A comprises a motor 608 with a stator 610 and a rotor (the rotor notvisible in FIG. 6). The rotor of the motor 608 is coupled to a leadscrew 222. The motor 608 may comprise any suitable electric motor thatcan turn the lead screw 222, such as a stepper motor, a direct current(DC) motor, or an alternating current (AC) motor (e.g., squirrel cage orsynchronous). Regardless of the type of motor 608, the motor 608 iscontrolled by the bed controller 118 (FIG. 1). In one exampleembodiment, the motor 608 is housed in a National ElectricalManufacturers Association (NEMA) 17 body, but other body types are alsocontemplated. In example embodiments, the stator 610 is coupled to thespring rail 200 in any suitable fashion; however, examples of how tocouple the stator 610 to the spring rail 200 are discussed in greaterdetail below.

In the representative adjustable spring assembly 600A, the lead screw222 is rigidly coupled to the rotor. Thus, as the rotor of the motor 608turns, so too does the lead screw 222, but the lead screw 222 does nottranslate along its longitudinal axis; rather, the orientation andpositon of the lead screw 220 relative to the upper surface 602 remainsthe same. Thus, the lead screw in the example embodiments is referred toas a captive lead screw. However, in other embodiments the lead screwmay be implemented as a non-captive lead screw, where turning of therotor translates the lead screw along the longitudinal axis of the leadscrew.

When assembled, the lead screw 222 extends above the upper surface 602of the spring rail 200. A spring perch or spring plate 612 is coupled tothe lead screw 222 such that as the lead screw 222 is turned by themotor 608, the spring plate 612 translates up and down along thelongitudinal axis of the lead screw 222. In embodiments where the leadscrew 222 is a captive lead screw, the axial relationship of the leadscrew 222 to the motor 608 does not change, and the spring plate 612 isthreadingly coupled to the lead screw 222 such that as the lead screw222 turns, the axial location of the spring plate 612 along the leadscrew 222 changes. In example embodiments, the lead screw 222 has an 8millimeter diameter, but larger and smaller diameters are alsocontemplated.

The representative adjustable spring assembly 600A further comprises themain spring 220 in the form of a helical spring having a first end 614and a second end 616. When assembled, the first end 614 of the mainspring 220 couples to the spring plate 612, and the second end abuts aninside surface of the baffle box 204 of fabric. In example embodiments,the main spring 220 is a helical spring that is “barreled”, meaning thatthe main spring 220 has a larger diameter at its medial portion, andsmaller diameters at the first end 614 and second end 616, thus takingthe exterior shape of an elongated whiskey barrel. Barreling of the mainspring 220 reduces buckling of the main spring under loads tending totorque the main spring 220 across the central axis of the main spring220. In other cases the main spring 220 may have a single diameter alongthe entire height. In accordance with at least some embodiments, themain spring 220 has a constant spring factor K along its length. Inother cases, however, the main spring 220 may have two or more springconstants along its length. In the example case of two spring constants,a first portion having a first spring constant K1 and a second portionhaving a second spring constant K2, where the first spring constant K1is different than the second spring constant K2. Having a main springwith two or more spring constants may enable finer control of the forcecarried for lighter loads.

Regardless of the exterior shape and/or how many spring constants themain spring 220 may implement, in example embodiments the spring has afree or un-laden height of between and including 5 inches to 20 inches,in some cases between 8 inches to 15 inches, and in a particular caseabout 11 inches. When the spring module 104 is fully assembled, thebaffle box 204 compresses or preloads each main spring 220, making thepre-load height between and including 4 inches to 19 inches, in somecases between and including 7 inches to 14 inches, and in a particularcase about 10 inches.

Still referring to FIG. 6, the example spring module 104 furthercomprises the baffle box 204. The example baffle box 204 is shown inpartial cut-away view to highlight some of the interior components. Thebaffle box 204 defines a top wall 620, a first side wall 622, a secondwall opposite the first side wall 622 (the second side wall not visiblein FIG. 6), a first end wall 624, a second end wall opposite the firstend wall 624 (the second end wall not visible in FIG. 6), and aninterior volume 626. Disposed within the interior volume 626 are aplurality of baffles (e.g., baffles 632, 634, 636, 638). The locationsof the remaining baffles are illustrated by dashed lines along the topwall and first side wall 622. Each baffle extends between the first sidewall 622 and the second side wall, and the plurality of baffles thuscreate or define a plurality of pockets within the baffle box 204. Whenassembled, each pocket of the baffle box 204 is telescoped over arespective main spring 220 of a respective adjustable spring assembly600. In example cases, each pocket of the baffle box 204 is coupled on alower end directly or indirectly to the spring rail 200. In some cases,each pocket of the baffle box 204 is coupled to a top plate of the motor600, as will be discussed in greater detail below.

The baffle box 204 in example cases is made of fabric material, andserves several purposes. First, the baffles (e.g., baffles 632, 634,636, 638) physically separate the main springs 220 from each other toreduce or eliminate the possibility of the spring coils interfering witheach other. Moreover, the baffle box 204 acts to slightly compress andthus pre-load each main spring 220. Further still, the baffle box 204physically couples the main springs 220 to each other to providestructural support against forces tending to displace the tops of themain springs 220 away from alignment with the longitudinal axis of thelead screws 222. In yet still other cases, the baffle box 204 may alsoact alone or in combination with other components to hold the springplate 612 against rotation when the motor 608 is turning the lead screw222 (e.g., by holding the upper ends of the main springs againstrotation).

In some cases the baffle box 204 and slip cover 202 (FIG. 2) areseparate components. In other cases, the baffle box 204 is sewn into theslip cover 202 (e.g., the edges that define the top wall 620 are sewnwithin corresponding locations of the slip cover 202). However, in othercases the functionality of the baffles and the industrial design aspectsof the slip cover 202 may be combined into a single component.

As the name implies, each adjustable spring assembly 600 is designed andconstructed such that the force carried by each main spring 220 can beadjusted. When the bed controller 118 (FIG. 1) determines a particularadjustable spring assembly 600 should carry more force, the motor 608 isactivated to move the spring plate 612 away from the spring rail 200 andtoward the sleeping surface 102 (FIG. 1). Moving the spring plate 612away from the spring rail 200 compresses the main spring 220 and thusthe main spring 220 carries more weight or force. Oppositely, when thebed controller 118 determines a particular adjustable spring assembly600 should carry less force, the motor 600 is activated to move thespring plate 612 toward the spring rail 200 and away from the sleepingsurface 102. Moving the spring plate 612 toward the spring rail 200 thusde-compresses the main spring 220 and thus the main spring 220 carriesless weight or less force.

While in some embodiments it is possible that the bed controller 118 maycontrol force carried by each adjustable spring assembly 600 in anopen-loop sense (e.g., without measuring the weight or force carried byeach adjustable spring assembly), in yet still other cases the weight orforce carried by each adjustable spring assembly 600 is measured by wayof a force sensor. For example, a force sensing mat may be placed overthe spring modules 104 after installation. In other cases, each springmodule 104 may be associated with a dedicated force sensing mat (e.g.,coupled to or forming the upper wall 620 of the baffle box 204). In yetstill other cases, each adjustable spring assembly 600 may have anassociated force sensor, such as by way of a strain gauge associatedwith the each motor 608.

FIG. 7 shows a perspective view of an adjustable spring assembly(without the main spring), and in accordance with at least someembodiments. In particular, the example adjustable spring assembly 600of FIG. 7 shows the motor 608, the lead screw 222, and the spring plate612. The description turns first to the spring plate 612.

The spring plate 612 is coupled to the lead screw 222 as discussedabove, with the precise type of coupling dependent upon how the leadscrew 222 couples to the rotor of the motor 608 (e.g., captive andnon-captive lead screw). The example spring plate 612 defines an annularshoulder 709 that circumscribes the location of the lead screw 222, anda stop, such as annular flange 708, that extends outward from below theannular shoulder 709. The lower end of the main spring 220 (not shown)couples to the spring plate 612 by telescoping over the annular shoulder709 and resting on the annular flange 708. The example spring plate 612further defines an anti-rotation aperture 710 through the spring plate612 and disposed between the location of the coupling to the lead screw222 and the annular flange 708. As the name implies, when present theanti-rotation aperture 710 works in conjunction with a post 712 to holdthe spring plate 612 against rotation during periods of time when themotor 608 is turning the lead screw 222. The example spring plate 612further comprises a set of spring clips 714 disposed on and radiallyspaced around an upper surface of the spring plate 612. FIG. 7 showsthree spring clips, but one or more spring clips may be present. Thespring clips 714 may be used to hold an additional and optional spring,referred to as a massage spring (discussed in greater detail below). Thespring clips 714 are designed and constructed such that as the massagespring is pushed downward over the spring clips 714, the spring clips714 may deflect slightly inward (e.g., deflect toward a longitudinalcentral axis 716 of the lead screw 222), and then snap over and hold thewire forming the lower-most loop of wire of the massage spring. Finally,the example spring plate 612 defines a zero-position post 718. Theexample zero-position post extends downward from a lower surface of thespring plate 612. In example embodiments, the zero-position post 718works in conjunction with a micro-switch (exposed through aperture 720,but not visible) to inform the motor controller when the spring plate612 has reached is lowest or zero position (which may also be a positionwhere the respective main spring carries the least force).

The motor 608 comprises the stator 610 as well as an upper or top plate704 and a lower or bottom plate 706. The top plate 704 and bottom plate706 hold the stator 610 together and in place. In the example embodimentof FIG. 7, the top plate 704 is a two-piece component comprising ametallic plate 722 directly abutting the stator 610, and an adapter 724coupled over and abutting the metallic plate 722. The adapter 724defines several additional features, such as the post 712 and theprotrusions 726 and 728. In other cases, however, the top plate 704 maybe an integral component defining all the various features (e.g., post712 and protrusions 726 and 728). Hereafter, reference will be made tothe top plate 704 with the understanding that any feature mentioned maybe an integral portion of the top plate 704, or may be implemented by anadapter (e.g., 724) coupled to the top plate 704. The post 712 extendsupward from the top plate 704, and a longitudinal central axis 730 ofthe post 712 is parallel to the longitudinal central axis 716 of thelead screw 222. As noted above, the post 712 works in conjunction withthe anti-rotational aperture 710 to help hold the spring plate 612against rotation, and thus the post 712 may be referred to as ananti-rotation post 712.

Still referring to FIG. 7, the example top plate 704 further includesthe buttons or protrusions 726 and 728. In example cases, theprotrusions 726 and 728 share a longitudinal central axis 732, and theprotrusions 726 and 728 extend outward in opposite directions from thetop plate 704. In the example shown, the longitudinal central axis 732of the protrusions is perpendicular to the longitudinal central axis 716of the lead screw 222. In some cases, the protrusions 726 and 728 arethe locations to which the baffle box 204 (FIG. 6) couples at thelocation of each adjustable spring assembly 600. In other words, theprotrusions 726 and 728 may be the affixation devices 228 shown in FIG.2. Moreover, as discussed more below, the protrusions 726 and 728 mayalso act to ensure rotational alignment of the adjustable springassembly 600 during coupling of the adjustable spring assembly 600 tothe respective spring rail 200.

In the example embodiment of FIG. 7, the bottom plate 706 is amultiple-component assembly comprising a mounting plate or suspensionmember 734, a control PCB 736, and cover piece 738. In exampleembodiments, the suspension member 734 is metallic and directly abutsthe stator 610. The suspension member 734 is associated with a forcesensor (not visible in FIG. 7), where the force sensor is configured tomeasure an amount of weight or force carried by the adjustable springassembly 600. In particular, the example suspension member 734 definestwo ears or tabs 740 and 742. The tabs 740 and 742 extend outward and inthe same directions as the example protrusions 726 and 728. When theadjustable spring assembly 600 is coupled to a respective spring rail,the adjustable spring assembly 600 is suspended by the tabs 740 and 742,and more particularly the stator 610 and all the components above thestator are suspended above the tabs 740 and 742. Stated otherwise, whenassembled the adjustable spring assembly 600 is rigidly coupled to thespring rail by way of the tabs 740 and 742, and the adjustable springassembly 600 is suspended above the bottom plate 706.

The example bottom plate 706 further comprises a control PCB 736sandwiched between the suspension member 734 and the cover piece 738. Inexample embodiments, electrical connections between various componentsmay be made merely by coupling the three components together. Forexample, a motor controller disposed on the control PCB 736 may beelectrically coupled to electrical pins within a connector (e.g.,connector 744) and the windings of the stator 610 of the motor 608 bystacking the three components together. In other cases, the cover piece738 may be omitted, and the control PCB 736 may be fully or partiallyexposed on the bottom side of the adjustable spring assembly 600. Theelectrical aspects of control of the adjustable spring assembly arediscussed in greater detail below. Each adjustable spring assembly 600comprises a pig tail or electrical cable 750 and correspondingelectrical connector 752. Thus, the electrical connector 752 is designedand constructed to couple to a corresponding electrical connector 744 ofan immediately adjacent adjustable spring assembly 600.

FIG. 8 shows a bottom view of the suspension member 734 in accordancewith at least some embodiments. In particular, the example suspensionmember 734 includes the tabs 740 and 742 extending outward, along withthrough bores 800. Affixation devices (e.g., screws) that are not shownextend through the through bores 804 to couple the suspension member 734to the stator 610 (FIGS. 6 and 7). Within the main body of thesuspension member 734 there is a force sensor 802 in the example form afirst strain gauge 804 associated with the tab 740 and second straingauge 806 associated with tab 742. Together the strain gauges 804 and806 are designed and constructed to measure the weight or force carriedby suspension member 734, and thus carried by the adjustable springassembly 600. More particularly, strain gauge 804 measures strainassociated with tab 740, and strain gauge 806 measures strain associatedwith tab 742. The total weight or force carried may thus be calculatedbased on the strain associated with tabs 740 and 742. Having two straingauges is merely an example, and any suitable force sensor that measuresweight or force carried may be used. The force sensor 802 isoperationally coupled to the bed controller 118 (FIG. 1) by way of thecontrol PCB 736 (FIG. 7). In example embodiments the force sensor 802electrically couples to the control PCB 736 by way of electricalconnector 808. That is, the electrical connector 808 is designed andconstructed such that aligning the control PCB 736 with the suspensionmember 734, and then abutting the control PCB 736 against the suspensionmember 734, mechanically and electrically couples the electricalconnector 808 to a mating connector on the control PCB 736 (the matingconnector not shown in FIG. 8). The force sensor 802 (and control PCB736) provide a value indicative of force to the bed controller 118.Thus, when an adjustable spring assembly 600 is mechanically coupled toa spring rail 200, the force carried by the adjustable spring assembly600 is measured by the force sensor 802 (and other circuits on thecontrol PCB 736).

The most distal portions of the tabs 740 and 742 define a distancebetween them, the distance delineated in FIG. 8 as W_(TAB). In examplecases, the distance W_(TAB) is greater than a distance between theinterior walls of the downwardly projecting legs 402 and 604 of thespring rail 200, where the distance between the interior walls ismeasured perpendicularly to the length L_(SR) (FIG. 6). Moreover, eachof the example tabs 740 and 742 define a tab length delineated in FIG. 8as L_(TAB). In example cases, the tabs 740 and 742, and the distancesW_(TAB) and L_(TAB), play a role in coupling the adjustable springassembly 600 to a spring rail 200, which in some cases is tool-lessoperation.

Returning to FIG. 6, and referring to adjustable spring assembly 600A asrepresentative. Coupling adjustable spring assembly 600A involvestelescoping the lead screw 222 and spring plate 612 through the firstaperture 606A of the spring rail 200, the telescoping from below thespring rail 200 such that the lead screw 222 and spring plate 612 extendabove the upper surface 602 of the spring rail 200. Once the lead screw222 and spring plate 612 are telescoped through the spring rail 200, theexample method comprises affixing the motor 608 to the spring rail 200,and coupling the main spring 220 to the spring plate 612. Eachadjustable spring assembly 600 is thus coupled in a similar fashion(e.g., telescoping the lead screw and spring plate, affixing the motor,and then coupling the main spring to the spring plate). In the examplecases discussed, coupling the main spring 220 occurs after telescopingof the lead screw 222 and spring plate 612 because the largest diameterof the main spring 220 (e.g., at the medial portion) is larger than ausable largest dimension (e.g., diameter) of the aperture 606. However,in cases where the main spring has a diameter smaller than a usablelargest dimension of the aperture 606, the main spring 220 may becoupled to the spring plate 612 prior to telescoping the lead screw 222through the aperture 606, and thus the act of telescoping the lead screw222 will also telescope the main spring through the aperture 606.

Regardless of the precise order of the steps to get the lead screw 222and spring plate 612 in the noted orientation, the motor 608 is affixedto the spring rail by being mechanically coupled to the spring rail 200.In at least some example embodiments, affixing the motor 608 to thespring rail 200 comprises rotating the motor 608 relative to the springrail, the rotation about the longitudinal central axis of the lead screw222, to engage elements of the suspension member 734 to the spring rail200. Rotating the motor 608 about the longitudinal central axis of thelead screw 222 may comprise rotating 180 angular degrees or less, insome cases rotating 90 angular degrees or less, and in a particular caserotating 45 angular degrees or less.

Turning again to FIG. 7, and still considering coupling of an adjustablespring assembly 600 to the spring rail 200. When the lead screw 222 andspring plate 612 are telescoped through the aperture 606, the motor 608and suspension member 734 have a rotational orientation such that thetabs 740 and 742 fit between, and do not interfere with, the downwardlyprojecting legs 402 and 604 (FIG. 6) of the spring rail 200. Statedotherwise, because the distance W_(TAB) (FIG. 8) between the most distalportions of the tabs 740 and 742 is greater than a distance between theinterior walls of the downwardly projecting legs 402 and 604, totelescope the lead screw 222, spring plate 612, and motor 608 through anaperture 606, the motor 608 is placed in a rotational orientation wherethe distance W_(TAB) forms an acute angle of less than 45 degreesrelative to the length L_(SR) of the spring rail 200, and in some casesthe distance W_(TAB) is aligned with the length L_(SR) during insertion.Once the lead screw 222, spring plate 612, and at least a portion of thetop plate 704 are telescoped through the aperture 606, the motor 608 andsuspension member 734 are rotated (e.g., by applying a rotational forceto the cover piece 738) such that the tabs 740 and 742 engage with thedownwardly projecting legs 402 and 604, respectively.

FIG. 9 shows a perspective view of an adjustable spring assembly 600coupled to a spring rail 200 in accordance with at least someembodiments. In particular, visible in FIG. 9 are a portion of anexample spring rail 200, along with a portion of an adjustable springassembly 600. The portion of the spring rail 200 visible in FIG. 9includes two full apertures 606A and 606B, and a partial aperture 606C.Aperture 606C is shown in partial cut-away to reveal an example springlatch 418. The example spring latch 418 is coupled to the downwardlyprojecting leg 402, and would also be coupled to the downwardlyprojecting leg 604, but a portion of the downwardly projecting leg 604is also cut away to show the spring latch 418. The example spring latch418 defines the proximal end 420 coupled to the downwardly projectingleg 402, the coupling by any suitable affixation devices (e.g., screws,rivets, spot welding). Also visible is the ridge 422 designed andconstructed to couple over a frame rail (not visible in FIG. 9).

Still referring to FIG. 9, and returning to considerations of thecoupling of an adjustable spring assembly 600 to the spring rail 200.The example spring rail 200 defines the downwardly projecting legs 402and 604. The example downwardly projecting legs 402 and 604 define slots900 in operational relationship to each aperture 606, though only theslots associated with the downwardly projecting leg 604 are visible inFIG. 9. The number of slots 900 along each downwardly projecting leg 402and 604 may correspond directly to the number of apertures 606, and thusin some cases between 8 and 40 slots 900 are present along eachdownwardly projecting leg 402 and 604. FIG. 9 shows and labels the onlytwo slots visible in FIG. 9 (900A and 900B) on downwardly projecting leg604. Each individual slot 900 will be referred to as “slot 900,” andgroups of slots will be referred to as “slots 900.” The slots 900 arespaced along the length L_(SR) (FIG. 6) of the spring rail 200, and eachslot 900 extends from an outer surface of its respective downwardlyprojecting leg to an inner surface thereof (i.e., the surface facing theopposite downwardly projecting leg). The slots 900 work in conjunctionwith the tabs 740 and 742 to affix or couple a motor 608 of theadjustable spring assembly 600 to the spring rail 200.

Referring to slot 900B as representative. Representative slot 900B has alength L_(S), where the length L_(S) is measured parallel to the lengthL_(SR) (FIG. 6) of the spring rail 200. The length L_(S) of the slot900B is slightly larger than the length L_(TAB) of either tab 740 or tab742 (FIG. 7). Moreover, the example slot 900B defines two heights,comprising a first height H1 being slightly larger (e.g., between andincluding 1 to 3 millimeters larger) than height H2. Height H1 is largerthan a thickness of the tab 740 or 742, and height H2 is smaller (e.g.,equal to the thickness of a tab 740 or 742). The difference in heightcreates a situation where, as the adjustable spring assembly 600 isturned about the longitudinal central axis of the lead screw 222, thetabs 740 and 742 can only enter the respective slots 900 as the motor608 is turned in one rotational direction. In the example case of FIG.9, the tabs 740 and 742 will only protrude into the slots 900 when themotor 608 is turned to the right (when viewed from below). As anadjustable spring assembly 600 is turned to couple or affix the motor608 to the spring rail, the tabs 740 and 742 protrude into theirrespective slots 900, with the small height H2 tending to form afriction fit with the respective tab to help hold the tab in the slot900. When tabs 740 and 742 are coupled within their respective slots andcan turn no farther, the rotational orientation defines an installed orlocked orientation. Regardless, once installed, the motor 608 (and inparticular the suspension member 734) is rigidly coupled to the springrail 200. Moreover, the example suspension member 734 suspends the motor608, the lead screw 222, the spring plate 612, and the main spring 220above the suspension member 734. Thus, slots 900 are examples of aplurality of means for engaging a respective suspension member 734.

The tabs 740 and 742, and corresponding slots 900 in the spring rail,are one example of systems and methods to couple or affix the motor 608to the spring rail 200. One of ordinary skill in the art, with thebenefit of this disclosure, could create many equivalent mechanisms forcoupling the motor 608 to the spring rail 200. For example, eachdownwardly projecting leg could be constructed to create an inwardlyprojecting ledge (e.g., cutting a “U”-shaped piece and bending the pieceinward, or installing ledge member on each downwardly projecting leg),and the suspension member 734 constructed with corresponding slots thatinteract with the ledges. In yet still other cases, one or moreaffixation devices (e.g., screws) may be installed through eachdownwardly projecting leg and into the suspension member 734 to hold themotor 608 in place.

Returning briefly to FIG. 7. In accordance with example systems, eachadjustable spring assembly 600 electrically couples to an adjacent ornearest neighbor adjustable spring assembly 600 along a respectiveshared spring rail 200. In order to reduce the length of electricalcable 750 extending between any two adjustable spring assemblies 600,the adjustable spring assemblies 600 are designed and constructed tocouple to the respective spring rail 200 in only one rotationalorientation relative to the spring rail 200 about the longitudinalcentral axis of the lead screw 222. For example, with each adjustablespring assembly 600 coupled in a consistent rotational orientation, theelectrical cable 750 of each adjustable spring assembly 600 protrudes orextends from its adjustable spring assembly 600 in the same directionrelative to the spring rail 200. The example tabs 740 and 742, by virtueof how the tabs 740 and 742 couple to the respective downwardlyprojecting legs 402 and 604, limit the affixed relationship of the motor608 to the spring rail 200 to two rotational orientations, and thus thetwo rotational orientations result in the possibility of the electricalcable 750 protruding in two opposite directions.

In example embodiments, each spring rail 200 and each adjustable springassembly 600 implement alignment features that ensure that the motor 608of the adjustable spring assembly 600 can be coupled or affixed to thespring rail 200 in only one rotational orientation relative to thespring rail (and about the longitudinal central axis of the lead screw222). In particular, in example systems each aperture 606 of each springrail 200 has at least one alignment feature, and each top plate 704 ofeach adjustable spring assembly 600 has at least one corresponding orcomplementary alignment feature, that ensures that the top plate 704 cantelescope through an aperture 606 in only one rotational orientation. Insome cases, once the alignment features clear each other, the adjustablespring assembly 600 may be free to rotate, but the tabs 740 and 742 andslots 900 limit further rotation.

FIG. 10 shows an exploded, partial perspective, and partial cut-away,view of an adjustable spring assembly 600 and spring rail 200 inaccordance with at least some embodiments. In the example of FIG. 10,the alignment features are shown as protrusions from the top plate 704(e.g., protrusions from the adapter 724), and corresponding notches inthe aperture 606. In particular, the example top plate 704 defines threeprotrusions. The first two protrusions are protrusions 726 and 728, andthus the protrusions 726 and 728 serve double duty in the examplesystem, being used both as alignment features for telescoping the motor608 through the aperture 606, and to couple to the pockets defined bythe baffle box 204. Inasmuch as the two protrusions 726 and 728 share acentral axis 732, in order to ensure that the top plate 704 willtelescope through the aperture 606 in only one rotational orientation, athird alignment feature in the form of a ridge 1000 is also defined bythe top plate 704. The example ridge 1000 has a rectangularcross-section, and is positioned at a radial location centered betweenthe radial locations of the protrusions 726 and 728. However, in othercases the ridge 1000 may be placed at any suitable radial location, andthe ridge may take any suitable cross sectional shape (e.g., square ortriangular). Having three example protrusions thus limits the rotationalorientations that the top plate 704, and thus the motor 608, willtelescope through the aperture 606 to a single telescoping rotationalorientation. In case where the protrusions 726 and 728 are omitted, asingle protrusions may be sufficient to ensure proper rotationalalignment.

FIG. 10 further shows a portion of an example spring rail 200, includinga single aperture 606. It is noted, however, that given the modularcharacter of the adjustable spring assemblies 600, correspondingly someor all the apertures 606 in a spring rail 200 may be identical. Theexample aperture 606 defines alignment features in the form of notches1002, 1004, and 1006. Notch 1002 corresponds to protrusion 728. Notch1004 corresponds to ridge 1000. And notch 1004 corresponds to protrusion726. Thus, as the top plate 704 is telescoped through the aperture 606,the protrusions move through their respective notches, forcingrotational alignment of the top plate 704 to only one rotationalorientation. In accordance with example embodiments, the protrusions726, 728, and 1000 have a height (measured parallel to the longitudinalcentral axis 716 of the lead screw 222) less than a distance D betweenthe protrusions and the tabs 740 and 742. Thus, once the protrusionsclear the upper surface 602 of the spring rail 200, the top plate 704and motor 608 may again rotate about the longitudinal central axis 716of the lead screw 222 to enable the tabs 740 and 740 to couple into theslots 900. However, in other cases, the one or more alignment featuresassociated with the motor 608 may limit rotation any time the top plate704 is telescoped through the aperture 606 (e.g., when the motor 608 isaffixed to the spring rail 200 by affixation devices such as screws orrivets).

While the top plate 704 shown in FIG. 10 defines the alignment featuresas protrusions, and while the aperture 606 defines the alignmentfeatures as notches, the distribution of the alignment features is notso limited. For example, in other cases the aperture 606 may have inwardfacing ridges while the top plate 704 (e.g., adapter 724) hascorresponding notches. Moreover, the alignment features with respect tothe top plate 704 need not be consistent. For example, the top plate 704may have one or more protrusions and one or more notches, and theaperture 606 will thus have one more corresponding ridges and one ormore corresponding notches. In any event, the alignment features areused to limit rotational alignment during telescoping of the top plateand motor 608 through the spring rail 200.

As alluded to with respect to FIGS. 7 and 10, each adjustable springassembly 600 comprises a control PCB 736 both mechanically andelectrically coupled to the motor 608. The control PCB 736 furthercommunicatively couples (e.g., electrically, optically) to other controlPCBs in other adjustable spring assemblies along a spring rail, and alsocommunicatively couples to the bed controller 118 (FIG. 1). Thespecification thus turns to example components that may be disposed onthe control PCB 736 of each adjustable spring assembly 600.

FIG. 11 shows an electrical block diagram of the control PCB inaccordance with at least some embodiments. In particular, the examplecontrol PCB 736 interfaces with components of the control PCB 736 by wayof a plurality of connectors, such as power connector 1100,communication connector 1102, force sensor connector 1104, and motorconnector 1106. The power connector 1100 may couple to both upstream anddownstream adjustable spring assemblies, and thus may be electricallyconnected to both the externally accessible electrical connector 744(FIG. 7) and electrical cable 750 (FIG. 7). In example cases, thecontrol PCB 736 is provided DC power (e.g., 12 VDC) to power the variouscomponents on the control PCB 736. Similar to the power connector 1100,the communication connector 1102 may couple to both upstream anddownstream adjustable spring assemblies, and thus may be electricallyconnected to both the externally accessible electrical connector 744(FIG. 7) and electrical cable 750 (FIG. 7). The force sensor connector1104 is designed and constructed to couple the mating electricalconnector 808 (FIG. 8) associated with the force sensor 802 (also FIG.8). And finally, the motor connector 1106 is designed and constructed tocouple to the winding or windings disposed within the stator 610 of themotor 608 (both FIG. 6).

In example systems, each control PCB 736 includes a controller 1108(e.g., a PIC16F19155 microcontroller available from Microchip TechnologyInc. of Chandler, Arizona). The example controller 1108 defines aplurality of input and output ports. For example, the controller 1108defines a transmit port 1110 and a receive port 1112. In the examplesystem, the transmit port 1110 couples to a protocol receiver 1114, andthe receive port 1112 couples to a protocol transmitter 1116. In examplesystems, the protocol receiver 1114 and the protocol transmitter 1116implement a communication protocol, such as an Institute of Electricaland Electronics Engineers (IEEE) RS485 serial communication protocol. Byway of the communication protocol, the bed controller 118 (FIG. 1) maycommand the controller 1108 to take action, such as increasing ordecreasing the weight or force carried by the adjustable spring assembly600 within which the controller 1108 is implemented.

The controller 1108 further includes an analog-to-digital (A/D) inputport 1118. In the example system, the ND input port 1118 may be used toread values indicative of force from the force sensor 802. Inparticular, the example system comprises an interface circuit 1120electrically disposed between the ND input port 1118 and the connector1104 (and thus the force sensor 802). The interface circuit 1120 mayimplement circuits used to power and/or read the force sensor 802. Theprecise nature of the interface circuit 1120 depends on the type offorce sensor implemented. In an example case the interface circuit 1120implements a differential amplifier, with the type of differentialamplifier dependent upon the precise nature of the force sensor 802.While in the example system the interface circuit 1120 couples to thecontroller 1108 by way the A/D input port 1118, other communicationsystems may be used (e.g., serial interface).

Still referring to FIG. 11, the example control PCB 736 furthercomprises a motor controller 1122. The motor controller 1122 iselectrically coupled to, and receives power from, the power connector1100. The motor controller 1122 couples to the motor connector 1106, andthus when assembled into an adjustable spring assembly 600 the motorcontroller 1122 couples to the winding or windings of the motor 608. Theprecise nature of the motor controller 1122 depends on the type of motor608 implemented within the adjustable spring assembly 600.

The controller 1108 defines a serial communication port 1124, and in theexample system the controller 1108 communicates with the motorcontroller 1122 over the serial communication port 1124. The serialcommunication port 1124, and related protocol, may take any suitableform (e.g., a serial peripheral interface (SPI)). In other cases, thecontroller 1108 may be communicatively coupled to the motor controller1122 by any suitable communication systems, including by sending and/orreceiving analog signals to the motor controller 1122.

The controller 1108 in some cases has onboard random access memory (RAM)and non-volatile storage (e.g., read-only member (ROM)), but in theexample system the controller PCB 736 also implements external RAM 1126and external ROM 1128. The example RAM 1126 and ROM 1128 arecommunicatively coupled to the controller 1108 by way of the serialcommunication port 1124, but any suitable communication system andprotocol may be used. The RAM 1126 may be used to store programsexecuted by a processor of the controller 1108 (the processor notspecifically shown), and in some cases the RAM 1126 may be the workingmemory for the controller 1108. Further still, the RAM 1126 itself mayimplement a non-volatile aspect (e.g., the RAM 1126 may be static RAM(SRAM)). The ROM 1128 may likewise be used to store programs executed bya processor of the controller 1108, including the underlying operatingsystem and basic input-output system (BIOS) services. The ROM 1128 maytake any suitable form, such as an electrically-erasable programmableROM (EEPROM).

Still referring to FIG. 11, the example control PCB 736 furthercomprises a set of identification switches 1130 coupled to thecontroller 1108. In particular, in the example system the controller1108 defines a plurality of digital inputs 1132. By way of the digitalinputs 1132, the controller 1108 may read the on/off state of eachswitch of the identification switches 1130. Using the identificationswitches 1130, the controller 1108, and thus the control PCB 736 andoverall adjustable spring assembly, can be uniquely identified by thebed controller 118. In other cases, however, identification of eachadjustable spring assembly make take place programmatically (e.g.,reading a unique media access control (MAC) address from each controlPCB), and thus the identification switches 1130 may be omitted, or usedfor other functions. For example, the switches may be used to identifymembership in a particular adjustable spring module 104, or the switchesmay be used to identify the first adjustable spring assembly in a springmodule 104 when the communication protocol relies on communicativelydaisy-chaining of the adjustable spring modules 600.

FIG. 12 shows a side elevation, partial cross-sectional view, of aportion of an adjustable spring assembly in accordance with at leastsome embodiments. In particular, shown in FIG. 12 is a side elevationview of the spring plate 612 coupled to the lead screw 222 and inoperational relationship to the post 712. The components of theadjustable spring assembly below the lead screw 222 and post 712 areomitted to provide further detail regarding the springs. In at leastsome embodiments the adjustable spring assemblies 600 comprise twosprings—a main spring 220 and a massage spring 1200. In FIG. 12, themain spring 220 is shown in cross-section to reveal the internal massagespring 1200. The main spring 220 is a helical spring that couples on thefirst end 614 by telescoping over the spring plate 612 and resting onthe annular flange 708. The lead screw 222 defines a longitudinalcentral axis 716. The main spring 220, in spite of being barrel shaped,has a central axis that is coaxial with the longitudinal central axis716. The optional massage spring 1200 defines a central axis that iscoaxial with the central axis of the main spring 220, and thus coaxialwith the longitudinal central axis 716 of the lead screw 222. In othercases, however, the massage spring 1200 may be shifted such that thecentral axis of the massage spring 1200 is parallel to, but not coaxialwith, the remaining central axes.

The massage spring 1200 defines a lower end 1204 and an upper end 1206.The lower end 1204 in the example systems is coupled to the spring plate612 by way of the spring clips 714. Only one spring clip 714 shown inFIG. 12, but more than one may be used. It is noted that the lower end1204 of the massage spring 1200 is also shown in partial cross-sectionto illustrate the spring clip 714 clipping over and holding the lowerend 1204 against the upper surface of the spring plate 612. Asillustrated by FIG. 12, the main spring 220 defines an un-laden lengthL_(MAIN), with the length as discussed above. The massage spring 1200likewise defines an un-laden length L_(MASSAGE) that is less than theL_(MAIN). When the length L_(MAIN) is about 10 inches, the lengthL_(MASSAGE) may be between and including 4 inches and 8 inches, and insome cases between and including 5 inches and 6 inches. In some cases,the massage spring 1200 has spring constant greater than the springconstant of the main spring 220, but in other cases the spring constantof the massage spring 1200 may be the same or smaller than the springconstant of the main spring 220. In accordance with example systems, themassage spring 1200 is used in conjunction with movement of the springplate 612 to implement an additional massage function for the overalladjustable sleeping system 100 (FIG. 1). In particular, under command ofthe bed controller 118 (FIG. 1), the adjustable spring assembly 600 mayquickly drive the spring plate 612 upward to fully compress the mainspring 220, and thus enabling the upper end 1206 of the massage spring1200 to extend at least to the second end 616 of the main spring 220,and in some cases extend above the second end 616 of the main spring220, to provide a more concentrated force to the body of the user of theadjustable sleeping system 100. It follows that the spring constant ofthe massage spring 1200 is higher than the spring constant of the mainspring 220.

Commercially available beds differ in many respects, but the primarydifferentiator is firmness. The measure of firmness differs bymanufacturer, but in most cases firmness is judged along a spectrum fromvery soft (sometimes “extra plush”) to extra firm. The exampleadjustable sleeping system 100 may emulate the entire firmness range. Inparticular, for a very soft setting the bed controller 118 may commandall the adjustable spring assemblies 600 to retract their respectivespring plates 612 to the position closest to the respective motors 608(e.g., the zero position discussed above). Thus, the user of the bedtakes advantage of the lower spring constant of the main spring 220.Oppositely, for a very firm setting the bed controller 118 may commandthe adjustable spring assemblies 600 to move their respective springplates 612 to the position closest to the second ends 616 of the mainspring 220. As discussed above, the pockets of the baffle box 204 and/orthe slip cover 202 limit spring travel, and thus the springs arepartially compressed against the baffle box 204. Thus, for a firm orextra firm setting the user of the bed takes advantage of the mainspring 220 being fully compressed and/or the extra support of themassage spring 1200.

While possible that the adjustable spring assemblies 600 could be usedsolely to implement firmness across the entire bed, the individuallyaddressable and controlled adjustable spring assemblies 600 providebetter granularity. In particular, in addition to or in place of thefirmness adjustability, example embodiments implement any of a number offorce control and/or normalization routines to lower the force appliedto any particular portion of the user's body.

FIG. 13 shows a method of assembly of a spring module 104 for anadjustable sleeping system 100, and in accordance with at least someembodiments. The method starts (block 1300) and comprises: coupling afirst adjustable spring assembly 600 to a spring rail 200 such that amain spring 220 of the first adjustable spring assembly 600 extendsabove an upper surface of the spring rail 200 (block 1302); coupling asecond adjustable spring assembly 600 to the spring rail 200 such that amain spring 220 of the second adjustable spring assembly 600 extendsabove the upper surface of the spring rail 200, the second adjustablespring 600 adjacent to the first adjustable spring assembly 600 (block1304); electrically coupling a communication channel of the firstadjustable spring assembly 600 to the second adjustable spring assembly600 (block 1306); and telescoping a baffle box 204 of fabric over themain springs 220 of the first and second adjustable spring assemblies600, and coupling the baffle box 204 to the spring rail 200 (block1308). Thereafter the method ends (block 1310), to be restarted forcoupling of the next adjustable spring assembly 600.

The above discussion is meant to be illustrative of the principles andvarious embodiments of the present invention. Numerous variations andmodifications will become apparent to those skilled in the art once theabove disclosure is fully appreciated. For example, an overall bed maybe conceptually (though not necessarily physically) divided such thattwo users could individually control their respective sides. Includingindividual control of firmness, massage, force normalization, spinealignment and/or any other function implemented by the bed system. It isintended that the following claims be interpreted to embrace all suchvariations and modifications.

What is claimed is:
 1. A method of assembly of a sleeping system,comprising: coupling a first spring module to a bed frame, the firstspring module comprising a plurality of spring assemblies that areadjustable, and the first spring module defining an upper surface;coupling a second spring module to the bed frame, the second springmodule comprising a plurality of spring assemblies that are adjustable,and the second spring module defining an upper surface; the uppersurfaces of the first and second spring modules defining a surfaceparallel to a sleeping surface of the sleeping system.
 2. The method ofclaim 1 wherein coupling the first spring module further comprises:coupling the first spring module to a first frame rail of the bed frame,the first frame rail extending along a length of the sleeping system,the length perpendicular to a width; and coupling the first springmodule to a second frame rail of the bed frame, the second frame railparallel to the first frame rail.
 3. The method of claim 2 whereincoupling the first spring module to the first frame rail furthercomprises sliding the first spring module across the first frame railuntil a first hinge member of the first spring module couples to asecond hinge member of the first frame rail, when coupled the first andsecond hinge members define a rotational axis parallel to the firstframe rail.
 4. The method of claim 3 wherein coupling the first springmodule to the second frame rail further comprises: rotating the firstspring module about the rotational axis; and latching the first springmodule to the second frame rail of the bed frame.
 5. The method of claim2 wherein coupling the second spring module further comprises: couplingthe second spring module to the first frame rail; and coupling thesecond spring module to the second frame rail, the second spring moduleimmediately adjacent to the first spring module along the width.
 6. Themethod of claim 5 wherein coupling the second spring module to the firstframe rail further comprises sliding the first spring module across thefirst frame rail until a third hinge member of the second spring modulecouples to a fourth hinge member defined on the first frame rail, whencoupled the third and fourth hinge members define a rotational axisparallel to the first frame rail.
 7. The method of claim 6 whereincoupling the second spring module to the second frame rail furthercomprises: rotating the second spring module about the rotational axisdefined by the third and fourth hinge members; and latching the secondspring module to the second frame rail of the bed frame.
 8. The methodof claim 1 wherein coupling the first spring module further comprises:coupling the first spring module to a first frame rail of the bed frame,the first frame rail extending along a length of the sleeping system;rotating the first spring module about a rotational axis parallel to thefirst frame rail, and the rotating toward a second frame rail; latchingthe first spring module to the second frame rail; and simultaneouslyelectrically coupling a first electrical connector of the first springmodule to a second electrical connector rigidly coupled to the secondframe rail.
 9. The method of claim 8 wherein coupling the second springmodule further comprises: coupling the second spring module to the firstframe rail of the bed frame; rotating the second spring module about arotational axis parallel to the first frame rail, and the rotatingtoward the second frame rail; latching the second spring module to thesecond frame rail; and simultaneously electrically coupling a thirdelectrical connector of the second spring module to a fourth electricalconnector rigidly coupled to the second frame rail.
 10. The method ofclaim 1 further comprising coupling an upper edge of the first springmodule to an upper edge of the second spring module.
 11. An adjustablesleeping system, comprising: a first plurality of spring modulesarranged in a first column, each spring module of the first plurality ofspring modules defines a row within the first column; each spring moduleof the first plurality of spring modules comprises: a rail that definesa length; and a plurality of adjustable spring assembles coupled alongthe length of the rail; each adjustable spring assembly comprises: amotor that defines a stator coupled to the rail, and a rotor; a leadscrew coupled to the rotor of the motor; a spring plate coupled to thelead screw; and a spring have a first end mechanically coupled to thespring plate, and a second end opposite the first end; a bed controllercommunicatively coupled to each spring module, and the bed controllerconfigured to selectively control a load carried by each springassembly.
 12. The adjustable sleeping system of claim 11 furthercomprising: a bed frame defining a first frame rail and a second framerail, the second frame rail parallel to the first frame rail, and thefirst and second frame rails extend along the first column; each springmodule of the first plurality of spring modules coupled to the firstframe rail and the second frame rail.
 13. The adjustable sleeping systemof claim 12 further comprising: the first frame rail further comprises aplurality of first hinge members, each first hinge member of theplurality of first hinge members corresponding to a row within the firstcolumn; and each spring module defines a second hinge member, eachsecond hinge member coupled to a first hinge member on the first framerail.
 14. The adjustable sleeping system of claim 13 wherein each secondhinge member biases a respective spring module toward the first framerail.
 15. The adjustable sleeping system of claim 13 wherein each firsthinge member and second hinge member define a hinge point between arespective spring module and the first frame rail during installation.16. The adjustable sleeping system of claim 13 further comprising: thesecond frame rail further comprises a plurality of first latch members,each first latch member of the plurality of first latch memberscorresponds to a row within the first column; and each spring moduledefines a second latch member, each second latch member coupled to afirst latch member on the second frame rail.
 17. The adjustable sleepingsystem of claim 12 further comprising: the second frame rail furthercomprises a plurality of first latch members, each first latch membercorresponds to a row within the first column; and each spring moduledefines a second latch member, each second latch member coupled to afirst latch member on the second frame rail.
 18. The adjustable sleepingsystem of claim 11 further comprising a second plurality of springmodules arranged in second column adjacent to the first column, eachspring module in the second plurality of spring modules defines a rowwithin the second column, and wherein the rows of the first column alignwith the rows of the second column.
 19. The adjustable sleeping systemof claim 18 wherein the first column defines at least one selected froma group comprising: a cot size bed; a single size bed; a twin XL sizebed; and a twin size bed.
 20. The adjustable sleeping system of claim 18wherein the first column and the second column together define a bedsize being at least one selected from a group comprising: a King sizebed; a Queen-size bed; and a California King-size bed.